hittite j sci eng Hittite Journal of Science and Engineering 2148-4171 Hitit University The Unoccupied Surface States of the Cu 110 Substrate Zeybek Orhan Balikesir University, Department of Physics, Balikesir, TURKEY 09 30 2018 5 3 191 194 Copyright © 2014, Hittite Journal of Science and Engineering 2014 Hittite Journal of Science and Engineering

I nverse photoemission spectroscopy is one of the advanced surface science technique for measuring unoccupied surface states with sufficient accuracy. The unoccupied surface states of the Cu 110 substrate has been investigated using an inverse photoemission spectroscopy with energy resolution of 0.5 eV. In this study, it has been introduced new unoccupied surface states. These unoccupied states are obtained from bulk bands and placed mainly in the outermost atomic layer. These states have been compared and contrasted with experimental and theoretical results. It has been also shown that at the point of the surface Brillouin zone, reflectance anisotropy spectra of the Cu 110 substrate possesses an unoccupied and occupied surface states.

 Inverse photoemission spectroscopy Cu 110 substrate Unoccupied surface states Reflectance anisotropy spectra Surface Brillouin zone 1. Petek H, Ogawa S. Femtosecond time-resolved two-photon photoemission studies of electron dynamics in metals. Prog Surf Sci 56(4) (1997) 239-310. 2. Osma J, Sarria I, Chulkov EV, Pitarke JM, Echenique PM. Role of the intrinsic surface state in the decay of image states at a metal surface. Phys Rev B 59(16) (1999) 10591- 10598. 3. Bartynski RA, Gustafsson T, Soven P. Observation of an unoccupied surface state on Cu(110) by inverse photoemission. Phys Rev B 31 (1985) 4745. 4. Goldmann A, Dose V, Borstel G. Empty electronic states at the (100), (110), and (111) surfaces of nickel, copper, and silver. Phys Rev B 32 (1985) 1971. 5. Jacob W, Dose V, Kolac U, Fauster T, Goldmann A. Bulk, surface and thermal effects in inverse photoemission spectra from Cu(100), Cu(110) and Cu(111). Z Phys B Condens Matter 63 (1986) 459-470. 6. Petersen L, Schaefer B, Lægsgaard E, Stensgaard I, Besenbacher F. Imaging the surface Fermi contour on Cu (110) with scanning tunneling microscopy. Surf Sci 457 (2000) 319-325. 7. Straube P, Pforte F, Michalke T, Berge K, Gerlach A, Goldmann A. Photoemission study of the surface state at Y on Cu(110): Band structure, electron dynamics, and surface optical properties. Phys Rev B 61 (2000) 14072. 8. Kevan S. High-resolution angle-resolved photoemission study of the Cu(011) surface state. Phys Rev B 28 (1983) 4822. 9. Matzdorf R, Gerlach A, Hennig R, Lauff G, Goldmann A. A spectrometer arrangement for high-resolution angleresolved UV-photo-emission using linear-polarized laboratory photon sources. J Elec Spec and Rel Phen 94 (1998) 279. 10. Reihl B, Frank KH. Unoccupied electronic surface states on Cu(110). Phys Rev B 31 (1985) 8282. 11. Smith NV, Woodruff DP. Inverse photoemission from metal surfaces. Prog in Surf Sci 21 (1986) 295-370. 12. Dose V. Study of empty electronic states by inverse ultraviolet photoemission. J Phys Chem 88 (1984) 1681- 1690. 13. Smith NV. Inverse photoemission. Rep Prog Phys 51 (1988) 1227. 14. Himpsel F. Inverse photoemission from semiconductors. Surf Sci Rep 12 (1990) 3-48. 15. Woll J, Meister G, Barjenbruch U, Goldmann A. Harmonic generation and photoemission. Appl Phys A: Mater Sci Process 60 (1995) 173. 16. Schneider R, Dürr H, Fauster Th, Dose V. Temperature dependence of the inverse photoemission from copper surfaces. Phys Rev B 42 (1990) 1638. 17. Martin DS, Weightman P. Reflection anisotropy spectroscopy: a new probe of metal surfaces. Surf Interface Anal 31 (2001) 915-926. 18. Dose V. Ultraviolet Bremsstrahlung spectroscopy. Prog Surf Sci 13 (1983) 225. 19. Smith NV. Inverse photoemission and related techniques. Vacuum 33 (1983) 803-811. 20. Shockley W. On the Surface States Associated with a Periodic Potential. Phys Rev 56 (1939) 317. 21. Tamn I. Exchange forces between neutrons and protons and fermi theory. Z Phys 76 (1932) 848. 22. Chen CT, Smith NV. Energy dispersion of image states and surface states near the surface-Brillouin-zone boundary. Phys Rev B 35 (1987) 5407. 23. Speier W, Zeller R, Fuggle JC. Studies of total density of states of metals up to 70 eV above EF . Phys Rev B 32 (1985) 3597. 24. Tang D, Su C. Heskett D. The unoccupied electronic structure of Na/Cu(110). Surf Sci 295 (1993) 427-432. 25. Su C, Tang D, Heskett D. Two-dimensional unoccupied electronic band structure of clean Cu(110) and (1 × 2) Na/ Cu(110). Surf Sci 310 (1994) 45-51. 26. Memmel N. Monitoring and modifying properties of metal surfaces by electronic surface states. Surf Sci Rep 32 (1998) 91-163. 27. Bartynski RA, Gustafsson T. Experimental study of surface states on the (110) faces of the noble metals. Phys Rev B 33 (1986) 6588. 28. Smith NV. Phase analysis of image states and surface states associated with nearly-free-electron band gaps. Phys Rev B 32 (1985) 3549. 29. Redinger J, Weinberger P, Erschbaumer H, Podloucky R, Fu CL, Freeman AJ. Inverse-photoemission spectra and electronic structure of the Cu(110) surface. Phys Rev B 44 (1991) 8288. 30. Smith NV. Chen CT. Spectroscopic constraints on the potential barrier at metal surfaces. Surf Sci 247 (1991) 133-142. 31. Goldmann A, Donath M, Waltmann W, Dose V. Momentumresolved inverse photoemission study of nickel surfaces. Phys Rev B 32 (1985) 837. 32. Petersen L, Schaefer B, Lægsgaard E, Stensgard I, Besenbacher F. Imaging the surface Fermi contour on Cu(110) with scanning tunneling microscopy. Surf Sci 457 (2000) 319.